I want to know under what conditions does the Mittag-Leffler function ${E_{\alpha ,1}}(z),(0 < \alpha < 1)$ has no real zero, where
${E_{\alpha ,1}}(z) = \sum\limits_{k = 0}^\infty {\frac{{{z^k}}}{{\Gamma (\alpha k + 1)}}}$.
${E_{1,1}}(z) = \sum\limits_{k = 0}^\infty {\frac{{{z^k}}}{{\Gamma (k + 1)}}} {\text{ = }}{{\text{e}}^z}$ or ${E_{0,1}}(z) = \frac{1}{{1 - z}}$ has no zero, how about $\alpha \in (0,1)$?
None of these functions have real zeroes, because they can be written as moment generating functions of certain random variables $Y_\alpha$. More precisely, for $0<\alpha <1$ $$E_{\alpha,1}(z)=\mathbb{E} e^{zY_\alpha}$$ where $$X_\alpha:=(1/Y_{\alpha})^{1/\alpha}$$ has the extreme positive stable distribution with index $\alpha$ (Levy-distribution), i.e- Laplace transform $$Ee^{-pX_\alpha}=e^{-p^\alpha}$$ for $p\geq 0$. See W. Feller, Intro. Prob. Theo. Appl. II, (1971), p.453.
EDIT: at the time of this answer the OP did not specify that the zero should be real.
The order (as an entire function) of $E_{\alpha,1}$ is $\frac{1}{\alpha}$. It so happens that entire functions with non-integer order take all complex values infinitely often. So in general $E_{\alpha,1}$ will have infinitely many zeroes. I don't know offhand about the case $\frac{1}{\alpha}\in \mathbb{N}$ though. In that case you can use the functional equation of $\Gamma$.
